A Bioactive Trypanosoma cruzi Bromodomain Inhibitor from

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A bioactive Trypanosoma cruzi bromodomain inhibitor from chemically engineered extracts I. Ayelén Ramallo, Victoria Lucía Alonso, Federico Rua, Esteban Serra, and Ricardo L. E. Furlan ACS Comb. Sci., Just Accepted Manuscript • DOI: 10.1021/acscombsci.7b00172 • Publication Date (Web): 26 Feb 2018 Downloaded from http://pubs.acs.org on February 28, 2018

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A bioactive Trypanosoma cruzi bromodomain inhibitor from chemically engineered extracts

I. Ayelen Ramallo

ab‡

Ricardo L. E. Furlan

a

, Victoria L. Alonso

ab‡

, Federico Rua b, Esteban Serra

ac**

and

ab*

Facultad de Ciencias Bioquímicas y Farmacéuticas, Universidad Nacional de

Rosario, Suipacha 531, CP2000, Rosario, Argentina. b

Instituto de Investigaciones para el Descubrimiento de Fármacos de Rosario

(IIDEFAR, CONICET-UNR) Ocampo y Esmeralda, CP2000, Rosario, Argentina. c

Instituto de Biología Molecular y Celular de Rosario (IBR, CONICET-UNR)

Suipacha 531, CP 2000, Rosario, Argentina.

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KEYWORDS Chemically engineered extracts, Diversification, Bromodomain inhibitor; Oxime, Chagas disease

ABSTRACT

A set of chemically engineered extracts enriched in compounds including N-N and NO fragments in their structures was prepared. Bromodomain binding screening and bioguided fractionation led to the identification of one oxime hit that interacts with TcBDF3 with affinity in the sub-micromolar range and that shows interesting antiparasitic properties against the different life cycle stages of T. cruzi.

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INTRODUCTION

Given the sustained success of natural products scaffolds as platforms for drug discovery,1–3 different strategies to diversify natural products are atracting increasing attention.4,5 One such strategy is the chemical transformation of natural product mixtures, such as crude herbal extracts, to produce chemically engineered extracts (CEEs).6 These CEEs are produced through non-selective chemical reactions that introduce bioactivity relevant fragments or elements into a significant proportion of the natural molecules present in the mixtures used as the starting material.7–12 In this way, a high number of natural product-derived molecules can be produced in one pot. CEEs enriched in sulphur, bromine, fluorine, and nitrogen have been prepared and used as the source of a series of new bioactive compounds, including enzyme inhibitors,13–17 antimicrobial compounds,6 XIAP inhibitors,11 amyloidogenesis inhibitors,9 antivirals17 and DNA binding molecules.12 The strategy is particularly suited for the search of molecules that interact with not fully characterized biological targets (for instance, no crystallographic data available). Bromodomains are protein interaction modules that selectively recognize and bind to acetyl-lysine residues present in histone and non-histone proteins. The missregulation of bromodomains has been implicated in the development of a broad spectrum of diseases, making them an attractive target for drug discovery.18–21 The profound and broad pharmacology of bromodomain inhibition, especially that associated with the human BET family of bromodomains, has led to the progression of a number of small molecule assets into the clinic.22 However, targeting bromodomain inhibition to treat infections caused by eukaryotic pathogens has been

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far less explored. We and others have identified several bromodomain-containing proteins in protozoa that are essential for viability offering a new opportunity for the development of antiparasitic drugs.23 Three bromodomain-containing sequences have been characterized in the protozoan parasite Trypanosoma cruzi.24–27 One of them, TcBDF3, interacts with acetylated α-tubulin and is an interesting drug target due to its involvement in flagella morphogenesis and differentiation.26 T. cruzi causes Chagas disease that is endemic in 21 countries in Central and South America. Cases of Chagas disease are increasing in the United States, Canada and many European countries due to human migration. The World Health Organization estimates that 7 to 8 million people are infected with T. cruzi globally and more that 10,000 deaths occur annually.28 T. cruzi infection and Chagas disease are characterized by poor diagnostics, the absence of vaccines and inadequate treatment.29 Treatment options for Chagas disease are currently restricted to two drugs: benznidazole and nifurtimox. Both drugs produce numerous side effects such as allergic dermatitis, pruritus, fever and gastrointestinal intolerance.30,31 In consequence, there is an urgent need for safe and efficacious new drug treatments for both acute and chronic phases of the disease.32 In the present study we describe the preparation and evaluation of a series of CEEs as bromodomain inhibitors. These CEEs are enriched in nitrogen containing compounds produced trough reactions with hydroxylamine or hydrazine. The biological screening of this set of CEEs led to the discovery of a unexpected furan derived oxime that binds to the hydrophobic pocket of TcBDF3. The compound is a T. cruzi inhibitor, showing activity against all developmental

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stages of the parasite. This is the first report of the preparation of CEEs enriched with the N-O fragment, and their implementation as a source of bioactive compounds.

RESULTS AND DISCUSSION Carbonyl groups as target for the introduction of nitrogenous moieties The carbonyl group is one of the most common functional groups found in natural products,15,26 thus its chemical transformation leads to the chemical alteration of a substantial proportion of the natural products (NPs) present in a given plant extract.6 The carbonyl group reactivity towards nucleophilic nitrogen containing reagents has been used as an entry door towards the incorporation of nitrogen fragments in natural products derived structures.6 Although nitrogen atoms are present in a significant proportion of NPs, its abundance is lower than that observed in populations of molecules used as drugs. On average, drugs have 3.3 C-N per molecule whereas NPs have 1.88.33– 35

These differences are more pronounced when nitrogen containing fragments

are considered. For instance, within the nitrogen containing groups present in NPs included in the Dictionary of Natural Products (ChemNet Base),36 those containing two nitrogen atoms directly attached to each other (N-N) or one nitrogen atom attached to an oxygen atom (N-O) are rare, representing 0.93 % and the 0.27 % respectively.36 The percentage of drugs containing N-O or N-N is two times and six times higher, respectively, than the percentage of NPs containing those fragments.37

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Aiming at the chemical diversification of natural mixtures by incorporation of these fragments through carbonyl group transformation, a set of 12 crude methanol extracts (MEs) and 23 essential oils (EOs) from different botanical genus and families were treated with hydroxylamine hydrochloride producing 35 chemically engineered extracts, and with hydrazine monohydrate6 to produce another 35 chemically engineered mixtures that were expected to be enriched in the N-O or in the N-N fragment respectively. Trypanosoma cruzi bromodomain binding assay. The interaction between TcBDF3 and each of the 70 chemically engineered mixtures was characterized in vitro by measuring the changes in the intrinsic fluorescence of TcBDF3 upon exposure to increasing concentrations of the samples (Supporting information Table S1). Such fluorescence is produced mainly by a tryptophan (W) residue located in the hydrophobic pocket of the bromodomain and is quenched when a compound binds to the acetyl-lysine binding pocket. This method was successfully used to determine that human BET-bromodomain inhibitor iBET-151 interacts with TcBDF3.26 Four samples showed interactions with TcBDF3, three of them showed weak interactions: Cedrus sp. essential oil modified with hydrazine (CEE Csp in Figure 1a) and Foeniculum vulgare L. and Coriandrum Sativum L. essential oils both modified with hydroxylamine (CEEs FV and COS in Figure 1b). These three CEEs produced a 20 to 30% decrease in TcBDF3 fluorescence intensity at 20 µg/mL (Supporting information Figure S1). Interestingly, the Paspalum dilatatum Poir. crude extract modified with hydroxylamine decreased the intrinsic fluorescence of TcBDF3 in around 60% (CEE PD in Figure 1b). The fluorescence quenching produced by this

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complex mixture is similar to the one produced by the reference compound iBET-151 used at a concentration one order of magnitude lower. P. dilatatum, known as sticky heads or dallisgrass, is a perennial C4 grass native to South America. It is widely grown for forage in warm temperate regions, but it can also represent a problematic warm-season perennial weed.38 The quenching of TcBDF3 intrinsic fluorescence by PD CEE is concentration-dependent, as observed for the reference compound iBET151 (Figure 2). It is worth to note that this decrease in fluorescence was not observed for the parent P. dilatatum crude extract suggesting that one or more TcBDF3 ligands were generated during the diversification step with hydroxylamine.

Figure 1. Normalized intrinsic fluorescence of recombinant TcBDF3 with 20 µg/mL of the 70 CEEs with Hydrazine (a) or Hydroxilamine (b). iBET-151 was used as a positive control at 2 µg/mL. The white bar represents the normalized intrinsic fluorescence of recombinant TcBDF3 alone. ME, methanol extract; EO, essential oil.

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Figure 2. Normalized intrinsic fluorescence of recombinant TcBDF3 in absence and in presence of increasing concentrations of P. dilatatum crude extract (PD) and P. dilatatum ME modified with hydroxylamine (PDME2). iBET-151 was used as a positive control. Bioguided fractionation of PDME2 The most active chemically engineered extract PDME2 was subjected to a bioassayguided fractionation to identify the responsible molecule/s for the observed activity. Sequential chromatographic separations led to the isolation of 5-(ethoxymethyl)furan2-carbaldehyde oxime (1) as a mixture of its Z and E isomers (Scheme 1). Both compounds incorporate in their structures, fragments formerly present in the reagent (NH2OH) and the solvent (EtOH). These oximes could have been formed from one or more sugars of the extract (ex. fructose)39 through a series of sequential reactions including sugar isomerization and dehydration to form hydroximethylfurfural,40–42 which could be etherified by the solvent43–46 and react with NH2OH to produce the oximes (Scheme 2). In order to confirm the structures and to carry out binding

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studies, each oxime isomer was obtained by reaction of ethyl-5-(methoxy) furan-2carbaldehyde with hydroxylamine hydrochloride in ethanol at room temperature and isolated by chromatography.

Scheme 1. Oximes generated during the diversification of P. dilatatum with hydroxylamine hydrochloride.

Scheme 2. Conversion of fructose into Z-1.

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Oxime-TcBDF3 binding assay The interaction between each oxime isomer and TcBDF3 was evaluated by fluorescence quenching and by differential scanning fluorimetry (DSF) or Thermal Shift. The fluorescence spectra of TcBDF3 did not change when increasing amounts of Z-1 where added to the soluble protein, however the maximum intrinsic fluorescence of TcBDF3 decreased regularly in the presence of oxime E-1 (Figure 3 and Supporting information Figure S2). The fluorescence data for oxime E-1 were analysed by Stern-Volmer, modified Stern-Volmer and double logarithmic plots (Table 1, Supporting information Figure S3). The Stern-Volmer plot of E-1 showed a negative deviation (towards the x-axis) as previously reported for TcBDF3 with bromodomain inhibitors iBET-151 and (+)-JQ1 (Supporting information Figure S3). From the double logarithmic plot we were able to obtain the dissociation constant (Kd) (Table 1) for E-1 in the low-micromolar range that is ten times lower than the Kd obtained for iBET-151 and (+)-JQ1 with TcBDF3.26 In addition, binding of E-1 significantly increased the thermal stability of TcBDF3 with ∆Tm observed of 4.5°C, whereas no significant stability shifts were observed with Z-1. Within a family of proteins a linear correlation between DSF ∆Tm observed values and binding constants has been reported, with temperature shifts larger than 4°C corresponding to compounds with dissociation constants lower than 1 µM consistent with our results.47

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Figure 3. Fluorescence spectra of TcBDF3 (10 µM) with increasing amounts of Z-1 and E-1. λex = 295 nm.

Table 1. Values of Ksv, fraction of accessibility of fluorophores to the quencher calculated from the modified Stern–Volmer (f), association constant (Ka) and number of binding sites (n) calculated from the double-logarithmic plots. Modified Stern Volmer plot

Double-logarithmic plot

Ksv´ (µM-1)

f

R2

Ka (µM-1)

Kd (µM)

n

R2

0.02858

0.42

0.85

33.728

0.296

0.85

0.95

The modeled 3D structure of TcBDF348 was used to perform docking predictions to oxime E-1 using the Swissdock server.49 The best prediction locates oxime E-1 inside the hydrophobic pocket of TcBDF3 (Supporting information Figure S4).

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Cytotoxicity The effect of Z-1 and E-1 in the different life cycle stages of T. cruzi was evaluated in vitro. Amastigotes are present in the mammalian host, whereas epimastigotes and the infective metacyclic trypomastigotes are present in the insect vector. To calculate IC50 values in the different stages, parasites were counted by direct microscopy and, alternatively, parasites that have been genetically engineered to express the Escherichia coli β-galactosidase gene, lacZ, were used.50 The amount of βgalactosidase activity in a well is directly proportional to the number of transfected parasites per well, and this activity can be easily and accurately quantitated on 96-well tissue culture plates with a microplate reader as described in the methods section. Also, the cytotoxicity of the compounds in the Vero cell line using MTT to obtain selectivity indexes (SI) was evaluated (Table 2). Similarly to the results obtained in the binding assays, the anti-parasitic activity showed by each oxime isomer was notably different. Oxime E-1 shows a trypanocidal effect in the three life cycle stages of T. cruzi with IC50 values around 7 µM for epimastigotes and trypomastigotes and 12 µM for amastigotes. Oxime Z-1 was always less effective, with IC50 values between 2, 8 and 7 times higher than E-1. Since both isomers showed similar toxicity against Vero Cells, their SIs were considerably different: Z-1 did not show good selectivity whereas E-1 showed SI values between 5 and 8 depending on the parasite cycle stage. The IC50 values observed for oxime E-1 against epimastigotes and trypomastigotes are similar to the values observed for NFX and significantly lower than those of BZN.

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Table 2: aThe results are averages of three separate determinations. bIC50 = the concentration required to give 50% inhibition, calculated by non-linear regression analysis from number of parasites or β-galactosidase activity at the concentrations used (0-200 µM). cSelectivity index = IC50 Vero cells toxicity/IC50 activity of extracellular or intracellular forms of the parasite. dValues obtained by us using MMT assay that correlate with other authors.51–53 eValues obtained from literature.54–57 BZN,

intracelular amastigotes

48.97 ± 60.92 46.70 ± 12.34 34. 67 ± 15.13 50.80 ± 4.30 1

1

2

E-1

7.04 ± 1.35

57.66 ± 3.56 8

7

5

BZNd 18.16 ± 5.13 27.07 ± 4.23 3.92 ± 1.24

30 ± 12

2

1

8

NFXe 8 ± 3

115 ± 12

14

16

38

8.18 ± 3.60

7±2

12.37 ± 6.89

3 ± 1.5

Vero cells

epimastigotes

trypomastigotes

SIc

Z-1

intracelular amastigotes

trypomastigotes

IC50

(µM)a,b

benznidazol; NFX, nifurtimox.

epimastigotes

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It had been reported that a benzoxazepine scaffold modified with an O-methyloxime was able to bind to BRD4 and CBP human bromodomains.58 Also, oxime-containing molecules were described as novel Histone Deacetylase (HDAC) inhibitors.59 However, no reports have been found for parasitic bromodomains. Several furancontaining

compound

have

been

described

with

anti-parasitic

activity

(leishmaniasis,60 malaria61) but so far there are no reports of bromodomain-inhibitors with these chemotypes. We believe that the small size of compound E-1 and the

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binding and bioactivity results described here represent a good starting point to produce derivatives with improved bioactivity.62 In parallel, this chemotype of bromodomain inhibitor could be assayed against bromodomains from other organisms associated to the aetiology of other pathologies, like those from the BET family.63

CONCLUSIONS A series of crude herbal extracts and essential oils were used as starting material to produce 70 chemically engineered extracts through reaction with hydroxylamine or hydrazine. These complex mixtures of unknown composition are expected to contain a high number of compounds enriched in the N-N or the N-O fragments content. In vitro screening of the CEEs using a T. cruzi bromodomain binding assay and further purification lead to the identification of an unexpected oxime as a mixture of its Z and E isomers. Interestingly, both the bromodomain binding and the antiparasitic activity of each isomer were very different: the E isomer shows the strongest binding reported to date for TcBDF3 and an interesting cytotoxic activity against all forms of T. cruzi whereas the Z isomer does not bind to the bromodomain and is not toxic for the parasite. The active compound was probably generated by dehydration, etherification with the solvent and reaction with hydroxylamine of a natural component of one of the inactive starting crude extracts. This finding illustrates how the simultaneous generation of a high number of compounds by chemical transformation of complex natural mixtures, of mainly unknown composition, with reagents that introduce bioactivity relevant fragments, can facilitate the discovery of unexpected bioactive compounds.

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MATERIALS AND METHODS Dulbecco’s modified Eagle’s medium (DMEM) were purchased from Life Technologies, chlorophenol red-β-D-galactopyranoside (CPRG) was purchased from Roche. SYPRO Orange was purchased from Molecular Probes. N-Benzyl-2-nitro-1Himidazole-1-acetamide

(benznidazole)

was

purchased

from

Sigma

Aldrich.

Aluminum-blacked silica gel 60 F254 TLC layers were purchased from Merck (Darmstadt, Germany). Agar was purchased from Britania (Buenos Aires, Argentina). Sodium sulphate, hydrazine monohydrate, hydroxylamine hydrochloride and 3-(4,5dimethylthiazol-2-yl)-2,5-diphenyltretazolium bromide (MTT) were purchased in Sigma-Aldrich (St. Louis, MO, USA). iBET-151 was purchased from ApexBio (Houston, TX, USA). Column chromatography was performed using Analtech silica gel 150 Å pore, 35-75µm particles. Molecular exclusion column chromatography was performed on Sephadex® LH-20. Solvents were analytical grade or were purified prior to use by fractional distillation. 1

H NMR spectra were recorded on a Bruker avance II at 300 MHz in CDCl3, in the

presence of TMS (0.00ppm) as the internal standard. 13C NMR spectra were recorded on the same apparatus at 150 MHz with CDCl3 as solvent and reference (76.9 ppm); 13

C NMR assignments were made on the basis of chemical shifts and proton

multiplicities (COSY 1H−1H, HSQC, and HMBC). Mass spectra were recorded on a micrOTOF-Q II, Agilent G1315C Startlight DAD spectrometer. MS Parameters: Source type: ESI, Ion polarity: Positive, Set nebulizer: 3.0 Bar, Set dry heater: 200°C, Set dry gas: 6.0 L/min, Set capillary: 4500 V, Set end plate offset: −450 V, Set collision Cell RF: 150.0 Vpp.

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Thermal melting experiments were carried out using a StepOne real-time PCR machine (Applied Biosystems). Circular dicroism spectroscopy was carried out using a spectropolarimeter Jasco J-810 (Easton, MD, USA). The biological experiments were performed employing Spectropolarimeter (Jasco J810), Synergy HT multi-detection microplate reader (BioTek Instruments), Fluorescence Spectrophotometer Varian Cary Eclipse (Agilent Technologies), and StepOne real-time PCR machine (Applied Biosystems). Natural mixtures Essential oils. The EOs were purchased from EUMA (Bs. As., Argentina). The acquired EOs were: Abies alba Mill. Pinaceae (‘AAL’), Allium sativum L. Amaryllidaceae (‘AS’), Artemisia absinthium L. Asteraceae (‘AAB’), Artemisia dracunculus L. Asteraceae (‘AD’), Cananga odorata (Lam.) Hook.f. & Thomson Annonaceae (‘CO’), Cedrus sp. Pinaceae (‘Csp’), Cinnamomum cassia

(L.),

J.

Presl Lauraceae (‘CC’), Cinnamomum verum J. Presl Lauraceae (‘CV’), Citrus aurantifolia (Christm.) Swingle Rutaceae (‘CAF’), Citrus aurantium Rutaceae (‘CA’), Citrus aurantium var. bergamia Rutaceae (‘CAB’), Citrus limonum (L.) Burm.f. Rutaceae (‘CL’), Coriandrum sativum L. Apiaceae (‘COS’), Cupressus sempervirens L. Cupressaceae (‘CUS’), Cymbopogom citratus (DC.) Stapf Poaceae (‘CYC’), Eucalyptus globulus Myrtaceae Labill. (‘EG’), Litsea cubeba (Lour.) Pers. Lauraceae (‘LC’), Myristica fragrans Houtt. Myristicaceae (‘MF’), Origanum vulgare L. Lamiaceae (‘OV’), Pimenta racemosa (Mill.) J.W.Moore. Myrtaceae (‘PR’), Pogostemon cablin Benth. Lamiaceae (‘PC’), Salvia officinalis L. Lamiaceae (‘SO’), and Vetiveria zizanioides (L.) Nash Poaceae (‘VZ’).

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Methanol extracts. A sample (200 g) of dried and powdered material was refluxed with 3 x 4 L of methanol for 45 min. The extracts were combined after filtration, and the solvent was evaporated under reduced pressure by rotary evaporation. Plants were collected in Pergamino, Buenos Aires province, Argentina, during November 2005. Voucher specimens were deposited at the Universidad Nacional de Rosario Herbarium. Collected plants were: Allium cepa L. Amaryllidaceae (‘AC’) ID MO020703, Anagallis arvensis L. Primulaceae (‘AA’) ID MO251003, Baccharis notorsegilia Griseb., Asteraceae (‘BN’) ID MO25302, Baccharis ulicina Hook. & Arn. Asteraceae (‘BU’) ID MO25301, Descurainia appendiculata (Griseb.) O.E. Schulz Brassicaceae (‘DA’) ID MO100704, Hordeum stenostachys Godr. Poaceae (‘HS’) ID0-2502,

Paspalum dilatatum Poir. Poaceae (‘PD’) ID MO0-2501,

Rapistrum rugosum (L.) All. Brassicaceae (‘RR’) ID MO0-20602, Solanum sublobatum Roem. & Schult. Solanacea (‘SSu’) ID MO0-20601, Sorghum halepense (L.) Pers. Poaceae (‘SH’), Vicia sativa L. Fabaceae (‘VS’) ID MO0-21002, and Sphaeralcea bonariensis (Cav.) Griseb. Malvaceae (‘SB’) ID MO0-20702. Chemical diversification protocols Hydroxylamine hydrochloride reaction procedure. 400 mg of the natural mixture and 370.6 mg of hydroxylamine hydrochloride were stirred under reflux in 20 mL of ethanol during 7 h. The solvent was removed under reduced pressure, the crude was dissolved in dichloromethane: water (1:1) and the organic phase was separated. The aqueous phase was washed with dichloromethane (2 x 50 mL) and then it was acidified with hydrochloric acid (36.5%) up to pH=2 and washed with dichloromethane (3 x 50 mL). Finally, the aqueous phase was alkalinized with sodium hydroxide up to pH=12 and washed with dichloromethane (3 x 50 mL). The organic

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fractions were pooled, dried (sodium sulphate) and gravity filtered, and the solvent was removed by rotary evaporation. Hydrazine monohydrate reaction procedure. 400 mg of the natural mixture and 0.50 mL of hydrazine monohydrate were stirred under reflux in 20 mL of ethanol during 4 h. The solvent was removed under reduced pressure, and the hydrazine was eliminated following the procedure previously described for the reactions with hydroxylamine. PDME2 for fractionation. The hydroxylamine hydrochloride reaction procedure was scaled up to 22 g of P. dilatatum methanol extract to obtain 5.72 g of the CEE. Bioguided isolation and synthesis of E-1 and Z-1 The 5.3 g of PDME2 were chromatographed on Silica gel (dichlorometane: methanol gradient, 98:2 to 95:5) giving nine fractions (F1-F9). F3 (1.8 g) was chromatographed on Sephadex® (Hexane: chloroform: methanol, 1:1:2) giving six fractions (F3a-F3f). The active fraction F3d was enriched in the oximes E-1 and Z-1. Synthesis of 1. Hydroxylamine hydrochloride (134 mg, 1.95 mmol) was added to a solution of 5-(ethoxymethyl)furan-2-carboxaldehyde, (100 mg, 0.65 mmol) in absolute ethanol (10 mL), and the mixture was stirred for 30 minutes at room temperature. The ethanol was evaporated slowly under vacuum with the previous addition of Na2SO4. After evaporation, ethyl acetate (3 mL) was added to precipitate the excess of hydroxylamine hydrochloride that was then removed by filtration. The mixture was purified by liquid chromatography in hexane: ethyl acetate, gradient (90:10 to 80:20, each 2 %) to obtain E-1 (0.21 mmol, 32 % final yield) and Z-1 (0.38 mmol 59% final yield).

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The E,Z-isomerism was determined by NMR in comparison of the chemical shifts of the "aldehyde proton" (H0) in both geometric forms. The signal of H0 in the Z isomer in fural oximes is shifted upfield by 0.48 ppm compared with the E isomer (Supporting information S9 and S10). It is known that owing to the deshielding effect of the NOH group in oximes, the H0 signal in the spectrum of the E isomer is found at weaker field than in the spectrum of the Z isomer.64–66 Biological assays Protein purification. pDEST17-TcBDF3HA was transformed into Escherichia coli BL21, and the recombinant proteins (fused to a His tag and haemaglutinin tag) were obtained by induction with 0.1 mM isopropyl-β-D-thiogalacto-pyranoside overnight at 22°C. The protein was purified from the inclusion bodies as reported previously.67 The solubilized proteins were dialyzed against 0.1 mM phosphate buffer pH 8. The secondary structure of soluble proteins (5 µM) was measured by circular dicroism spectroscopy. Fluorescence spectra. For fluorescence spectra for Kd calculations a 2 mL solution containing 10 µM recombinant TcBDF3HA was titrated by successive addition of the oximes using concentrations ranging from 0 to 100 µM. Fluorescence spectra were acquired with an excitation wavelength of 295 nm and emission was recorded in the range of 300–450 nm. All fluorescence measurements were corrected with blank solution and with the emission spectra of each concentration of oxime. Taking into account the inner filter effect in the quenching process, the fluorescence intensity of TcBDF3 was corrected using the following equation: Fcorr = Fobs x 10 (Aexc+Aem)/2, where Fcorr and Fobs are the corrected and observed fluorescence intensity of TcBDF3HA, and Aexc and Aem are the absorption values of the system at

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the excitation and emission wavelength, respectively.68 Alternatively the same experiment was performed but in 96-well microplates (Fluotrac 200 black, Greiner BioOne) with 5 µM recombinant TcBDF3HA and three concentrations of crude extracts (5, 10 and 20 µg/mL), fractioned extracts or purified compounds. All determinations were made from the top with an excitation wavelength of 275 nm and a 340/30 nm emission filter, 50 reads per well and a PMT-sensitivity setting of 180 in a Synergy HT multi-detection microplate reader equipped with time resolved capable optics. The fluorescence quenching data were analyzed by the Stern–Volmer equation and the modified Stern–Volmer equation (Supporting information Figure S3). The values of the association or binding constant (Ka) for the compound–TcBDF3 interaction was determined from the double-logarithmic plots of log(F0 - F)/F vs log[Q]. The dissociation constant (Kd) is described as the reciprocal of Ka. Thermal shift. TcBDF3HA was buffered in 10 mM HEPES, pH 7.5, 500 mM NaCl and assayed in a 48-well plate at a final concentration of 2 µM in 20 µL volume. Compounds were added at a final concentration of 10 µM. SYPRO Orange (Molecular Probes) was added as a fluorescence probe at a dilution of 1:1000. Excitation and emission filters for the SYPRO Orange dye were set to 465 and 590 nm, respectively. The temperature was raised with a step of 2°C per minute from 25°C to 96 °C, and fluorescence readings were taken at each interval. Data was analyzed as previously described.69 Trypanosma cruzi culture. T. cruzi epimastigotes (Dm28c strain) were cultured at 28°C in liver infusion tryptose (LIT) medium (5 gL-1 liver infusion, 5 gL-1 bactotryptose, 68 mM NaCl, 5.3 mM KCl, 22 mM Na2HPO4, 0.2% (w/v) glucose and 0.002 % (w/v) hemin) supplemented with 10% (v/v) heat-inactivated Fetal Calf Serum

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(FCS). To obtain metacyclic trypomastigotes, epimastigotes were differentiated in vitro following the procedure described by Contreras and co-workers under chemically defined conditions using triatomine artificial urine medium (TAU)70. Vero cells were cultured in Dulbecco’s modified Eagle’s medium (DMEM; Gibco, Life Technologies, Carlsbad, CA), supplemented with 2 mM L-glutamine, 10% FCS, 100 UmL-1 penicillin and 100 gmL-1 streptomycin. Purified trypomastigotes were used to infect monolayers of Vero cells at a ratio of 10 parasites per cell. After 6 h of infection at 37 °C, the free trypomastigotes were removed by successive washes with phosphate-buffered saline (PBS). Cultures were incubated for 2 days post-infection to obtain amastigotes. Infections were performed in DMEM supplemented with 2 % FCS. Cells were then fixed in methanol and the percentage of infected cells and the mean number of amastigotes per infected cell was determined by counting the slides after Giemsa staining using a Nikon Eclipse Ni-U microscope, by counting ~ 1000 cells per slide. The significances of the results were analyzed with two-way ANOVA using GRAPHPAD PRISM version 6.0 for Mac (GraphPad Software, La Jolla, CA, USA). MTT assay. Cell viability after treatment was determined by the 3-(4,5dimethylthiazol-2-yl)-2,5-diphenyltretazolium bromide (MTT) reduction assay. Briefly, Vero cells (5.000 cells per well) were incubated in 96-well plate in the presence of the different compounds for 48 hours. Then 20 µL MTT solution (5mg/mL in PBS) were added to each well and incubated for 1 hour at 37°C. After this incubation period, MTT solution was removed and precipitated formazan was solubilized in 100 µL of DMSO. Optical density (OD) was spectrophotometrically quantified (λ= 540 nm) using a Synergy HT multi-detection microplate reader. DMSO was used as blank and each treatment was performed in triplicates.

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Beta-galactosidase assay. T. cruzi Dm28c that express the Escherichia coli LacZ gene was used.50 Epimastigotes, trypomastigotes or amastigotes obtained 48 hours postinfection of Vero cells monolayers were incubated with the compounds. After 72 h of treatment for epimastigotes, 24 hours for trypomastigotes and 48 hours for amastigotes the assays were developed by addition of CPRG (100 µM final concentration) and Nonidet P-40 (0.1% final concentration). Plates were incubated for 2 to 4 hours at 37°C. Wells with β-galactosidase activity turned the media from yellow to red, and this was quantitated by Absorbance at 595 nm using a Synergy HT multi-detection microplate reader as reported previously.71

ASSOCIATED CONTENT Supporting Information. This material include a figure of extracts that showed weak fluorescence quenching of TcBDF3, a Figure of quenching of TcBDF3 by Z-1 and E1, a figure of Stern-Volmer, modified Stern-Volmer and double logarithmic plots of TcBDF3 with E-1, and a figure of modeled 3D structure of TcBDF3 and docking prediction to E-1. The values of fluorescence measurements of modified extracts and essential oils assayed obtained in the microplate assay are also detailed. 1H NMR and 13

C NMR spectra of E-1 and Z-1 are showed.

AUTHOR INFORMATION Corresponding Author *To whom correspondence should be addressed. E-mail: [email protected]. Tel/Fax: +54 341 4375315.

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**To whom correspondence should be addressed. E-mail: [email protected]. Tel/Fax: +54 341 4350596 ext. 133 Author Contributions The manuscript was written through contributions of all authors. All authors have given approval to the final version of the manuscript. ‡These authors contributed equally. Funding Sources Financial support for this work was provided by FONCYT (PICT2015-3574), CONICET (PIP 695) and Universidad Nacional de Rosario to R.L.E.F., and PIP 0685 to E.C.S. I.A.R, V.L.A., F.R., E.C.S. and R.L.E.F. are CONICET researchers.

ACKNOWLEDGMENT The authors thank Mr Oscar Micheloni and Mr Luis Oakley (Ciencias Agrarias, Universidad Nacional del Noroeste de la Provincia de Buenos Aires) for plant material collection and identification.

ABBREVIATIONS CEEs, Chemically engineered extracts; NPs, Natural products; MEs, crude methanol extracts; EOs, essential oils; Csp, Cedrus sp.; FV, Foeniculum vulgare L.; COS, Coriandrum Sativum L.; PD, Paspalum dilatatum Poir; Paspalum dilatatum methanol extract modified with hydroxylamine (PDME2).

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